Zhang, Keyu; Cui, Dingfang; Huang, Xiaopeng; Liang, Feng; Gao, Geng; Song, Tingyu; Zhang, Libo; Yao, Yaochun; Lei, Yong:
Insights into the interfacial chemistry and conversion mechanism of iron oxalate toward the reduction by lithium
In: The chemical engineering journal, Vol. 426 (2021), Article 131446
2021Journal article in JournalClosed Access
Technische Universität Ilmenau (1992-) » Department of Mathematics and Natural Sciences (1992-) » Institute for Physics (1992-) » Fachgebiet Angewandte Nanophysik (2018-)
Title in English:
Insights into the interfacial chemistry and conversion mechanism of iron oxalate toward the reduction by lithium
Author:
Zhang, Keyu;Cui, Dingfang;Huang, Xiaopeng;Liang, Feng;Gao, Geng;Song, Tingyu;Zhang, Libo;Yao, Yaochun
SCOPUS
15841141400
Other
corresponding author
;
Lei, YongTU
GND
1187786403
ORCID
0000-0001-5048-7433ORCID iD
ResearcherID
A-7950-2012
SCOPUS
56152354500
SCOPUS
57727266700
SCOPUS
58136699000
SCOPUS
58552655800
SCOPUS
58722720400
SCOPUS
58796274800
SCOPUS
58997682100
Other
connected with university
Year of publication:
2021
Open-Access-Way of publication:
Closed Access
PPN:
Language of text:
English
Keyword, Topic:
Fachgebiet Angewandte Nanophysik <Ilmenau>
Media:
online resources
Type of resource:
Text
Peer Reviewed:
Yes
Part of statistic:
Yes

Abstract in English:

The origin of excellent lithium storage ability and high irreversible capacity is probably the least understood component for transition-metal oxalates as anode materials in lithium-ion batteries. Considerable efforts have been put into understanding their electrochemical reaction mechanisms, but these insights have mostly been unilateral and unsystematic. Herein, the interface characteristic between iron oxalate anode and electrolyte and detailed conversion process were investigated to explore the source of irreversible Li+ storage. In particular, a gelatinous "organic" layer identified oxygen, fluorine and phosphorus as the main chemical elements can be re-oxidized and exhibits an obviously reversible conversion between sedimentation and decomposition during its initial lithiation process, despite the general belief that it shows similar electrochemically inert to solid-electrolyte interphase (SEI). Meanwhile, this special interface layer leads to higher ability of Li+ ions diffusion and smaller charge-transfer resistance, which is the vital role for excellent rate capability. Furthermore, ex situ FTIR analysis confirms the formation and residue of new intermediate compound of Li2Fe(C2O4)2, thus making a part of initial irreversible capacity. It is also found that the iron oxalate electrode with larger capacitive contribution still has more widely application in energy storage of supercapacitors in future.